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The European Astronomical Society (EAS) awards the 2016 MERAC Prize for the Best Doctoral Thesis in the category “New Technologies” to MPE scientist Oliver Pfuhl for his thesis on an innovative design of two subsystems for the VLTI instrument GRAVITY: the fibre coupler and the guiding system. The MERAC Prize Committee was impressed by the high quality of the nominated candidates for the three MERAC Prizes of 2016. The official ceremony will take place during the European Week of Astronomy and Space Science (EWASS) to be held in Athens, Greece on 4 – 8 July 2016.

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Animation of the stellar orbits around the Galactic Centre. The star S2 will have its next closest approach to the black hole in 2018. Relativistic effects will then cause the orbit to shift by 0.2°.

MPE Press Release

The ideal black hole laboratory

Successful observations with GRAVITY and the ESO 8m Very Large Telescopes

June 21, 2016

A team of European astronomers has achieved a crucial milestone for testing Einstein's theory of general relativity with the closest supermassive black hole in the centre of our own galaxy. For the first time, the newly installed GRAVITY instrument has been used together with ESO's Very Large 8m Telescopes to observe a star orbiting the black hole on a period as short as 16 years. These tests have impressively demonstrated GRAVITY’s sensitivity to detect this star in just a few seconds of exposure time, which sets a record in optical interferometry by several magnitudes, and opens the door for observing Einstein’s general relativity at work around black holes. Both the target star and a reference star nearby show no signs of being binaries – making future measurements much less complex. This means that the team will be able in the near future to obtain ultra-precise positions of the orbiting star, and to test whether the motion around the black hole follows the laws of general relativity - or not. The new observations show that the Galactic Centre is as ideal a laboratory as one can hope for.

Image of the galactic centre. For the interferometric GRAVITY observations the star IRS 16C was used as a reference ... [more]

Image of the galactic centre. For the interferometric GRAVITY observations the star IRS 16C was used as a reference star, the actual target was the star S2. The position of the centre, which harbours the (invisible) black hole with 4 million solar masses, is marked by the red cross.

Image of the galactic centre. For the interferometric GRAVITY observations the star IRS 16C was used as a reference star, the actual target was the star S2. The position of the centre, which harbours the (invisible) black hole with 4 million solar masses, is marked by the red cross.

Located a mere 25000 light-years from the Solar System, in the Sagittarius constellation, the centre of the Milky Way hosts a massive black hole, 4 million times as heavy as the Sun. Its position and mass are well known since 2002, when the first complete orbit of the star S2 was recorded: Over the course of nearly 16 years, the star draws a tiny ellipse with a size of only 0.2 arcseconds on the sky. A football stadium placed on the moon would appear as large – or small – when seen from Earth. While with previous instruments the astronomers could measure the orbit accurately enough to determine the mass of the black hole, testing general relativity requires pinpointing the object with centimetre precision in the imaginary stadium on the moon.

The new instrument GRAVITY – developed in a collaboration by the Max Planck Institute for Extraterrestrial Physics (MPE) and Astronomy (MPIA), LESIA of Paris Observatory and IPAG of Université Grenoble Alpes/CNRS, the University of Cologne, the Centro Multidisciplinar de Astrofísica Lisbon and Porto (SIM), and the European Southern Observatory (ESO) – is specifically designed for that purpose. It is an interferometer, i.e. it combines the light of the four 8-metre telescopes of the VLT on top of the mountain Paranal in the Chilean Atacama desert. To further improve GRAVITY's sensitivity in deeply embedded and dust enshrouded regions like the Galactic Centre, each of the 8-metre telescopes is also being equipped with a new Coudé Infrared Adaptive Optics (CIAO) system.

The images at the top show the unresolved star S2 and the data obtained with GRAVITY (interferometric fringes) next to ... [more]

The images at the top show the unresolved star S2 and the data obtained with GRAVITY (interferometric fringes) next to it. The images below are for resolved stars: several sources (middle) and an extended source (bottom). In these cases, the fringes are increasingly blurred; this case can be excluded from the data.

The images at the top show the unresolved star S2 and the data obtained with GRAVITY (interferometric fringes) next to it. The images below are for resolved stars: several sources (middle) and an extended source (bottom). In these cases, the fringes are increasingly blurred; this case can be excluded from the data.

Combining the light interferometrically yields an effective resolution equal to that of a virtual telescope as big as 130 metres. The corresponding gain of a factor 15 in resolving power and precision over the 8-meter telescopes will open up the possibility for testing Einstein's theory in the Galactic Centre. Having built this ultra-precise machine over the course of the past decade, the team now faced two crucial questions: Will GRAVITY provide the required sensitivity for observing the faint stars orbiting the Galactic Centre? And would the Galactic Centre laboratory collaborate and offer clean “test particles” to accurately measure the effects predicted by Einstein’s theory of general relativity?

"It was a fantastic moment for the whole team when the light of the fast-orbiting star S2 interfered for the first time", says GRAVITY lead scientist Frank Eisenhauer from the Max-Planck-Institute for Extraterrestrial Physics in Garching, Germany. "First we actively stabilized the interference on a bright nearby star, and only a few minutes later we could really see the interference from the faint star S2 – to a lot of high-fives.” On first glance neither the reference star nor the orbiting star have bright and massive companions, which would complicate the observations and analysis. "They are ideal probes", explains Eisenhauer.

At its closest approach in 2018, the star S2 will pass by the black hole in a distance of only 17 light hours, being ... [more]

At its closest approach in 2018, the star S2 will pass by the black hole in a distance of only 17 light hours, being subject to extrem gravitational forces. [less]

At its closest approach in 2018, the star S2 will pass by the black hole in a distance of only 17 light hours, being subject to extrem gravitational forces.

But it was not only a technical challenge, but also a race against time: The rush for the GRAVITY observations is necessary because the star will pass closest to the black hole in 2018, where the sought-for relativistic effects are most pronounced. At this point the star will approach the black hole to a distance of only 17 light-hours, and will move at a speed of almost 8000 km/s, or 2.5% of the speed of light. That is a thousand times faster than the international space station ISS is orbiting Earth. In 2018, the S2 ellipse will change its orientation due to general relativity and will rotate in its plane by around 0.2°. This is orders of magnitude more than the relativistic effect affecting the orbit of Mercury, the Solar System’s innermost planet. The next opportunity after 2018 to observe the close passage of S2 around the black hole will only be in 2033.

Exciting times are ahead for black hole researchers!

Credit: Max Planck Institute for Extraterrestrial Physics (MPE)

Animation of the path an incoming light ray traces through the GRAVITY instrument. Note the intricate design and complex interaction of the various components for the four telescopes. For interferometry to work, the light paths have to be superposed with a precision of a fraction of the wavelength – less than 1 micrometre.